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Over a wide αd range there was little difference in pKa between both gels, as well as between the gel ...... Aintzane Pikabea , Jose Ramos , Jacquelin...
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Langmuir 1999, 15, 4283-4288

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Potentiometric Titration Behaviors of a Polymer and Gel Consisting of N-Isopropylacrylamide and Acrylic Acid† Hironori Suzuki, Benlian Wang, Ryo Yoshida, and Etsuo Kokufuta* Institute of Applied Biochemistry, University of Tsukuba, Tsukuba, Ibaraki 305, Japan Received September 8, 1998. In Final Form: January 25, 1999 We studied the ionization equilibria of the COOH groups bound to the copolymer and to the cross-linked copolymer network (i.e., gel) consisting of N-isopropylacrylamide (NIPA) and acrylic acid (AAc) by means of potentiometric titration with NaOH. Microgel particles (average hydrodynamic diameter ∼ 120 nm in the acid form and at 25 °C; COOH content ∼ 30 mol %) were employed, in addition to the usual bulk gel (of a fine grind) with the same COOH content. The microgel was prepared by aqueous redox polymerization using N,N′-methylenebis(acrylamide) as a cross-linker and sodium dodecylbenzenesulfonate as a surfactant. The titration was carried out at 25 and 35 °C in the absence and the presence of NaCl. The dependence of the apparent dissociation constant (pKa) on the degree of dissociation (Rd) was investigated. It was found that, on the whole, pKa increased with increasing Rd but decreased by addition of NaCl. Over a wide Rd range there was little difference in pKa between both gels, as well as between the gel and copolymer. At 35 °C and at Rd < 0.15, however, an increase in Rd brought about a distinct fall in pKa for the microgel as well as the copolymer. At Rd < 0.15, pKa was larger at 35 °C than at 25 °C. To discuss these results in connection with the swelling behavior of the gel, size changes of the microgel particles were studied using the photon correlation spectroscopy. The size of the microgel increased with increasing the degree of neutralization (Rn) but decreased by screening the COO- charges with counterions. Over the Rn range of 0.6 to 1.0, there was little or no increase in the particle size. These aspects were analogous to those generally observed in the chain expansion of poly(AAc) in solutions, suggesting that the “counterion binding effect” plays an important role in the swelling of NIPA/AAc gels at high charge densities. It was also suggestive that hydrogen bonding as well as hydrophobic interaction affects the ionization of COOH and thereby the swelling degree at 35 °C and at Rd < 0.15. Therefore, it may be concluded that our ionic NIPA gels swell through an increase in the net charge density due to the COO- ions rather than a rise in the osmotic pressure arising from mobile counterions within the gel phase.

Introduction Gels consisting of N-isopropylacrylamide (NIPA) and acrylic acid (AAc) undergo an abrupt volume change, i.e., volume phase transition, in response to pH and ionic strength as well as temperature. Since the earliest study on the volume phase transition of NIPA/AAc gels by Tanaka et al.,1 the polyelectrolyte gel of this sort has been employed in many studies, most of which were summarized in a review by Schild.2 Theoretical interpretations of the volume phase transition for NIPA/AAc gels, as well as those for other polymer gels, are usually made by relying on the Flory-Huggins mean-field equation of state consisting of four principal terms: the rubber elasticity, the interactions among polymer segments and solvents, the mixing entropy, and the osmotic pressure (e.g., see refs 2 and 3). As pointed out by Schild,2 the expressions of the three contributions to the free energy other than the osmotic pressure have varied from theory to theory with tenuous connections with reality in some cases. However, there was little disagreement regarding the description of osmotic effects; in other words, Donnan equilibria were consistently assumed. We have demonstrated that the binding of ionic surfactants to neutral NIPA gels results in a polyelectrolyte gel with an inhomogeneous distribution of charges due to * To whom correspondence should be addressed. † Presented at Polyelectrolytes ’98, Inuyama, Japan, May 31June 3, 1998. (1) Hirotsu, S.; Hirokawa, Y.; Tanaka, T. J. Chem. Phys. 1987, 87, 1392. (2) Schild, H. G. Prog. Polym. Sci. 1992, 17, 163 and references therein. (3) Hirotsu, S. Adv. Polym. Sci. 1993, 110, 1 and references therein.

the surfactant.4,5 Such an ionic gel was then found to exhibit a different swelling behavior from that of ionic NIPA/AAc gels prepared via the usual random copolymerization.6 This finding can no longer be explained on the basis of the Flory-Huggins equation handling the effect of ionic groups as changes in osmotic pressure arising from mobile counterions in the “overall” gel phase. To further study the influence of charge distributions, we have synthesized the two kinds of NIPA/AAc gels into which the AAc residues are homogeneously or inhomogeneously introduced.7 If the osmotic effect becomes a dominant factor, one might not observe any difference in the swelling curves between both NIPA/AAc gels. The reason for this is that counterions to the ionized groups should move freely within the whole gel phase surrounded by the Donnan potential barrier and thereby increase the osmotic pressure acting to swell the gel. However, our experiments have given convincing evidence that the charge distribution strongly affects the gel volume; therefore, this also argues against the interpretation of the volume phase transition for ionic NIPA gels in terms of osmotic pressure arising from mobile counterions. Another promising approach for learning the behavior of the counterions in the NIPA/AAc gel would be the examination of the ionization process of COOH groups with a base. This is, however, a rather difficult problem (4) Kokufuta, E.; Zhang, Y.-Q.; Tanaka, T.; Mamada, A. Macromolecules 1993, 26, 1053. (5) Kokufuta, E.; Nakaizumi, S.; Ito, S.; Tanaka, T. Macromolecules 1995, 28, 1704. (6) Kokufuta, E.; Suzuki, H.; Sakamoto, D. Langmuir 1997, 13, 2627. (7) Kokufuta, E.; Wang, B.; Yoshida, R.; Khokhlov, A. R.; Hirata, M. Macromolecules 1998, 31, 6878.

10.1021/la981187z CCC: $18.00 © 1999 American Chemical Society Published on Web 04/09/1999

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with respect to experimental techniques, for example, how to estimate the “real” acid-base equilibrium within the gel phase from the pH measurements of the outer solution. For this reason, no study has so far dealt with the potentiometric titrations of polyelectrolyte gels, except for ion exchangers (i.e., a highly cross-linked polyelectrolyte gel) and our cationic gels8 composed of lightly crosslinked poly(ethyleneimine) (PEI). For PEI gels, small particles with a size less than 1 mm were obtained by grinding and subjected to the pH measurements of the bulk solution into which the particles had been dispersed. As a result, we found that potentiometric titration is a useful way for explaining the pH changes in the swelling degree of the PEI gel on the molecular level. The object of the present study is to examine the dissociation behavior of the COOH groups in the NIPA/ AAc gels by means of potentiometric titration and to compare it with the results of swelling experiments; through this approach we intend to discuss the swelling mechanism of ionic NIPA gels at the molecular level. In particular, our attention has been paid to a role of mobile counterions, as well as those of hydrophobic interaction and hydrogen bonding. The submicrometer-sized gel particles with 70 mol % NIPA and 30 mol % AAc, in addition to the bulk gel of a fine grind, were employed in this study, because we have succeeded in preparing such microgel particles.9 We also employed the NIPA/AAc copolymer with the same AAc content as a control sample. One might expect that use of the microgel would help to eliminate a general problem in the pH titration for gels, that is, a great difficulty to judge whether the H+ and OH- concentrations within the gel phase come to equilibrium with those in the aqueous bulk phase at different stages of the titration. We should note that our microgel has most of the COOH groups located in the interior but not on the hydrodynamic surface of the particle. Experimental Section Materials. The copolymer was synthesized by radical polymerization using benzene as the solvent and R,R′-azobis(isobutyronitrile) as the initiator. The copolymerization of a benzene solution containing NIPA (70 mol %) and AAc (30 mol %) was carried at 75 °C for 20 min under nitrogen. The resulting reaction mixture was slowly poured into n-hexane to precipitate the polymer, which was then separated by filtration, washed with n-hexane, and dried in a vacuum. Purification was carried out by dialyzing an aqueous polymer solution against distilled water for 1 week. The dialyzed solution was lyophilized and finally dried under reduced pressure at 50 °C for 3 days. A bulk gel (a transparent gel mass) was prepared by the usual gelation method, i.e., redox polymerization of an aqueous solution containing NIPA (490 mM), AAc (210 mM), and N,N′-methylenebis(acrylamide) (Bis; cross-linker; 8.6 mM) which can be initiated by a pair of ammonium persulfate (APS; 3.68 mM) and N,N,N′,N′-tetramethylethylenediamine (TMED; 0.48% v/v). The gelation of the monomer solution (pregel) was performed in a test tube at 20 °C for 3 days under nitrogen. After the gelation was completed, a gel mass was taken out of the test tube, broken into pieces, passed through a screen with a mesh size of 1 mm, and fully washed with a large amount of distilled water. The purified samples were completely converted into the acid form (i.e, the gel with COOH) by dialyzing against 0.01 M HCl and then lyophilized for 3 days. Microgel particles used were the same as those prepared and purified in our other contribution to this special volume (see ref 9). (8) Kokufuta, E.; Suzuki, H.; Yoshida, R.; Yamada, K.; Hirata, M.; Kaneko, F. Langmuir 1998, 14, 795. (9) Ito, S.; Ogawa, K.; Suzuki, H.; Wang, B.; Yoshida, R.; Kokufuta, E. Preparation of Thermosensitive Submicrometer Gel Particles with Anionic and Cationic Charges. Langmuir 1999, 15, 4289.

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Figure 1. Potentiometric titration curves with 0.1 M NaOH in the absence (a) and the presence (b) of 0.1 M NaCl for the copolymer (closed circles), the bulk gel (open triangles), and the microgel (open circles) at 25 °C. Potentiometric Titration. Potentiometric titration with 0.1 M NaOH was performed at 25 or 35 °C under nitrogen. Both aqueous copolymer solutions and aqueous gel suspensions (50 mL each) were used as the sample; their ionic strengths were adjusted with NaCl. The sample concentration (Cp in the molarity of COOH groups) was 5.94 ( 0.01 mM in all the cases. Threetime-distilled carbonate-free water was used as the solvent. A back-titration was also performed with 0.1 M HCl for the bulk and the microgel suspension (ionic strength ) 0.1) which had been titrated with the NaOH (front-titration). The batchwise addition of titrant was performed using a buret with a precision of (0.01 mL, when the pH reached a steady value (within a change of (0.01 pH units over a monitoring period of 10 min). The sample was stirred at ca. 70 rpm during the titration. A Horiba pH-meter (mode F-22) equipped with a combination pH electrode (Horiba model 6378-10D) was used for pH measurements. The electrodes were calibrated by using phosphate and potassium acid phthalate buffers. Size Measurements. The apparent Stokes diameters (ds) of the microgels were measured under the same conditions as used in the titration using photon correlation spectroscopy (PCS). The Cumulant method was used in the analysis of dynamic light scattering data. The sample concentrations were 0.2% (w/v) in all measurements.

Results and Discussion Potentiometric Titration Curves. The first requirement for the present purpose is to accurately determine the quantities of COOH groups in the copolymer and gel samples. Figure 1 shows the titration curves with 0.1 M NaOH for two kinds of gels as well as the copolymer in the absence and the presence of 0.1 M NaCl. The titration

A Polymer and Gel Consisting of NIPA and AAc

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Table 1. Carboxyl Group Contents of the Copolymer and Two Kinds of the Gels Determined by Volume of 0.1 M NaOH at the End Point of Titrations COOH content (mmol‚g-1 of dry mass) at various ionic strengths 0a sample copolymer bulk gel microgel a

0.05a

0.1a

0.2a

25 °C 35 °C 25 °C 35 °C 25 °C 35 °C 25 °C 35 °C 2.72 2.94 2.85

2.73

2.82

2.74

2.80

2.73

2.74

2.78 2.96 2.74

2.82

2.77

2.94

2.73

2.79

2.75

Adjusted with NaCl.

curves for the gels were obtained by plotting the pH of the outer medium against the titrant volume (Vt). A very clear end point was observed in each titration curve; thus, the overall content of COOH was easily determined from Vt at the end point (see Table 1). There was little difference in the COOH content between the gels, as well as between the gel and the copolymer. The same result was also obtained when titration was carried out at 35 °C, the temperature of which is slightly higher than the phase transition temperature (Tν; ∼33 °C) of neutral NIPA gels or the lower critical solution temperature (LCST; ∼31 °C) of NIPA polymer. Another piece of important information from Figure 1 is that the titration curves of both gels show a striking resemblance to that of the copolymer. From this, we may suggest that the dissociation of protons from the COOH groups bound to the linear polymer chain and the crosslinked polymer network is essentially the same. However, one might doubt whether the pH between the gel phase and the bulk solution with suspended gels was equilibrated or not. Taking this into account, we performed a backtitration with HCl after the bulk or the microgel in the acid form was titrated with NaOH beyond the Vt at the end point. As can be seen from Figure 2, there was little difference in the results between the front- and the backtitration not only for the microgel, but also for the bulk gel. This indicates that our titration data for both the gels do not include serious errors relating to a pH difference between the gel and the bulk phase. Relation between Dissociation Constant and Degree of Dissociation. A complete titration curve can be given by plotting apparent dissociation constant (pKa) against the degree of dissociation (Rd). We may determine pKa from the titration data using the following relations:

(

pKa ) pH - log

Rd 1 - Rd

)

Rd ) Rn + (CH+ - COH-)/Cp

(1) (2)

Here, Rn is the degree of neutralization and CH+ and COHare the molar concentrations of H+ and OH- ions, respectively. If we write the required electrostatic free energy for the removal of an equivalent of protons at a given Rd as ∆Giel(Rd), its relation to pKa may be given as10

∆Giel(Rd) pKa ) pK + 0.43 RT 0

(3)

where pK0 is characteristic of the ionizing group under conditions where electrostatic interactions with other ionizing groups are absent. Moreover, R denotes the gas constant and T the absolute temperature. (10) For example: Morawetz, H. Macromolecules in Solutions; John Wiley-Interscience Publishers: New York, London, Sydney, 1965; pp 348-356.

Figure 2. Changes in pH during titrations of the microgel (a) and the bulk gel (b) with 0.1 M NaOH (open circles) followed by back-titration with 0.1 M HCl (closed circles) [ionic strength ) 0.1 (NaCl), 25 °C].

The NIPA/AAc gel undergoes a volume phase transition in response not only to pH and ionic strength but also to temperature; thus, it would be interesting to examine the dependence of pKa upon Rd as a function of ionic strength and temperature. We studied the effect of ionic strength on the Rd dependence of pKa at 25 and 35 °C (Figures 3 and 4). The latter temperature is slightly higher than the Tν of NIPA gel and the LCST of NIPA polymer. Since our copolymer and gels in the acid form may be taken as a neutral NIPA, the phase separation and the volume phase transition should take place during the titration at 35 °C. Thus, it would be interesting to see how these effects appear in the dependence of pKa on Rd. However, we did not perform the titration of the bulk gel at 35 °C because (a) the characteristic times of swelling and deswelling for NIPA gels are proportional to the square of a linear dimension of the gel and (b) the transition becomes very slow when temperature comes close to Tν.11 The titration curves in Figures 3 and 4 provide us with some significant information: (i) On the whole, pKa increases with increasing Rd but decreases with addition of NaCl. (ii) There is little difference in pKa between the gels, as well as between the gel and copolymer. (iii) At 35 °C and at Rd < 0.15 (see Figure 4), however, an increase (11) Matsuo, E. S.; Tanaka, T. J. Chem. Phys. 1988, 89, 1695.

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Figure 3. Changes in apparent dissociation constant (pKa) with the degree of dissociation (Rd) for the copolymer (closed circles), the bulk gel (open triangles), and the microgel (open circles) in the absence (a) and the presence (b) of 0.1 M NaCl at 25 °C. A very slight initial fall in pKa was observed in the salt-free system with the copolymer. This was reproducible and not an experimental error; thus, it seems that in the case of the copolymer the interaction (being discussed in the text) appears not only at 35 °C but also at 25 °C.

in Rd leads to a distinct fall in pKa for both gel and copolymer; their pKa values at 35 °C are larger than those at 25 °C. Result i is the general aspect appeared in the titrations of polymeric acids, such as poly(AAc), in the absence and the presence of added salt (e.g., see refs 10 and 12). From an increase in pKa with Rd, meaning that the removal of H+ from the polymeric acid becomes increasingly difficult as the titration proceeds, we may learn of an increase in ∆Giel(Rd) due to the electrostatic attraction between H+ ions and polyanions. Since the counterions from added salts contribute to weakening this attraction through the elimination of polyion charges, ∆Giel(Rd) should decrease over a wide Rd range. Then, we may see a decrease in pKa displaying that the dissociation of H+ from the polymer becomes easy. Therefore, result ii indicates that the ionization mechanism for the gels is essentially the same as that for the polymer solution. If we take the above into account, result iii may be explained as follows. At the initial stage of the titration (Rd ∼ 0) and at 35 °C, both copolymer and cross-linked copolymer network should be in a collapse state due to hydrophobic interaction. This shortens the distance of a (12) Kokufuta, E. Polymer 1980, 2, 177.

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Figure 4. Changes in apparent dissociation constant (pKa) with the degree of dissociation (Rd) for the copolymer (closed circles) and the microgel (open circles) in the absence (a) and the presence (b) of 0.1 M NaCl at 35 °C.

COOH group from the surrounding functional groups; thus, interactions of this COOH with the neighboring groups would become strong (i.e., the “nearest neighbor interaction” originally proposed by Katchalsky et al.13). Actually, poly(NIPA) and poly(AAc) give forth a waterinsoluble complex under conditions where the COOH groups are fully protonated.7 Under such conditions, however, the complexation does not take place in the presence of 4 M urea, suggesting that the complexation mechanism is due to hydrogen bonding between -COOH and -CONH- groups; for example,

If this is the case, the removal of the H+ from the COOH should be impeded. Consequently, pKa at 35 °C became larger than that at 25 °C. By ionization of a few COOH groups with NaOH, however, a mutual repulsion among the resulting COO- ions weakens by degrees the nearest neighbor interaction. This should facilitate the dissociation of other COOH groups (a decrease in pKa with Rd). Indeed a turbidity appeared both in the salt-free and the salt(13) Katchalsky, A.; Mazura, J.; Spitnik, P. J. Polym. Sci. 1957, 23, 513.

A Polymer and Gel Consisting of NIPA and AAc

Figure 5. Changes in apparent Stokes diameter (ds) of the microgel with the degree of neutralization (Rn) in the absence of NaCl at 25 °C (open circles) and 35 °C (closed circles).

Figure 6. Changes in apparent Stokes diameter (ds) of the microgel with the degree of neutralization (Rn) in the presence of 0.1 M NaCl at 25 °C (open circles) and 35 °C (closed circles).

containing solutions of the copolymer at 35 °C, but the solution became transparent as the titration proceeded (Rd > 0.1 for the salt-free system; Rd > 0.16 for the saltcontaining system). In the case of the microgel system at 35 °C, a turbidity was also observed in the presence of NaCl (Rd < 0.1) but not in pure water. This provides a key to supporting the above interpretation (see the following section). Effects of pH, Ionic Strength, and Temperature on the Size of the Microgel. It would be interesting to learn how the size (or the swelling degree) of the NIPA/ AAc microgel particle varies depending on the ionization of the COOH groups as well as on temperature. For this purpose, we plotted ds against Rn as a function of temperature (see Figures 5 and 6). The results obtained in pure water (Figure 5) and in 0.1 M NaCl solution (Figure 6) were then reported separately, because there was a large difference in the magnitude of size changes caused by the absence and the presence of the salt. With the ionizing of the COOH groups, the particle size linearly increased at Rn < 0.6 and then leveled off at Rn > 0.6; this feature was remarkable in the salt-free system rather than in the NaCl-containing system. With screening of the charge of COO- ions with the counterions from NaCl added, the size decreased over a wide Rn range, except for the result in the salt solution at 35 °C and at Rn < 0.1 (see Figure 6). These aspects are quite analogous to the changes in the end-to-end extension of poly(AAc) ions in aqueous

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solutions. Kokufuta12 has performed the viscometric and electrophoretic studies with aqueous poly(AAc) solutions and obtained the following results (see ref 14): (a) An increase in ionic strength results in a marked decrease in the viscosity as an indication of the end-to-end extension of a polymer chain. (b) The viscosity increases with increasing Rn at Rn < 0.6 and levels off at Rn > 0.6. (c) These viscosity changes correspond to the mobility changes, because the mobility may be considered as an indication of the net charge density of a polyion when it behaves as a free draining coil in electrophoresis. Among results a-c, we draw particular attention to the fact that the charge density scarcely increases at Rn > 0.6. In general, this phenomenon is known as the “counterion binding effect”, strong experimental evidence for which has been reported by Wall et al.15 From their transference experiments using radioactive sodium (22Na) in salt-free aqueous solutions containing poly(AAc) partially neutralized with NaOH, we may learn the following important two features: (1) The binding degree of Na+ ions linearly increases at Rn < 0.6 and levels off at Rn > 0.6. (2) The concentration of mobile Na+ ions increases linearly at Rn < 0.2, gradually at 0.3 < Rn < 0.7, and rapidly again at Rn > 0.8. By comparing these results with those of potentiometric titrations in the previous section, let us consider a role of Na+ ions in our gel system. Then, we may assume that at Rn > 0.6 at which the gel little swells, the concentration of mobile Na+ ions still increases. According to the Flory-Huggins theory for polyelectrolyte gels, a very slight increase in the concentration of mobile counterions within the gel phase brings about a dramatic increase in the swelling degree (e.g., see ref 16). Therefore, our results in Figures 5 and 6 may not be understood by assuming that an increase in Rn raises osmotic pressure arising from mobile counterions within the “overall” gel phase. Otherwise, by considering that at Rn > 0.6 the net charge density of the gel little increases but levels off due to the counterion binding, the dependence of the swelling degree upon Rn may favorably be accounted for. As a result, we may see the strong resemblance between the Rn changes in the swelling degree for the NIPA/AAc gel and in the end-to-end extension for poly(AAc) in solutions. We examined in detail the effect of temperature on the size of the microgel in pure water at Rn < 0.3 (see a window in Figure 5). At Rn < 0.15, the particle size at 35 °C was smaller than that at 25 °C because of Tν ∼ 33 °C for neutral NIPA gels. However, this difference disappeared at Rn ∼ 0.15 at which the gel has 4.5 mol % “COONa” plus 25.5 mol % COOH. These mean that our microgel undergoes “thermal” swelling transitions at Rd < 0.15 when lowering temperature from 35 °C to 25 °C (see ref 17). We have discussed in the previous section why the initial fall in pKa, as well as the solution turbidity, appears both in the salt-free and the salt-containing systems not only with the copolymer but also with the microgel, under conditions at 35 °C and at Rd < 0.15. For the copolymer, these phenomena were satisfactorily accounted for in terms of the nearest neighbor interaction, in which hydrogen (14) Both viscosity and mobility data have been reported in ref 12 as a function of pH. However, these can be converted into a relation with Rn (or Rd), because the reference includes the titration curves by pH vs Rd as well as pKa vs Rd. (15) Huizenga, J. R.; Grieger, P. F.; Wall, F. T. J. Am. Chem. Soc. 1950, 72, 2636. (16) See in addition to refs 1-3 the following: Tanaka, T.; Fillmore, D. J.; Sun, S.-T.; Nishio, I.; Swislow, G.; Shah, A. Phys. Rev. Lett. 1980, 45, 1636. (17) This result agrees with that reported by Hirose et al. (Macromolecules 1978, 20, 1342), who studied the temperature dependence of the swelling degree for submicrometer NIPA gel particles with different amounts of the COONa groups.

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bonding and hydrophobic interactions play an important role. Although the turbidity did not appear in the saltfree microgel system, the results in the window of Figure 5 clearly indicate that the microgel particles are in a collapse state at Rd < 0.15 and at 35 °C. Under such a situation, we may reasonably assume the nearest neighbor interaction mechanism to account for the initial fall of pKa in the microgel system. As a result, the swelling behavior of our polyelectrolyte gel may be understood, without relying on models based upon the Flory-Huggins theory, through detailed considerations of the mechanism for the dissociation of COOH at the molecular level, even when a slight amount of NaOH was added in the gel system to ionize the COOH groups. We must discuss separately the Rn change of ds for the microgel in the salt-containing system, because the turbidity has been observed at 35 °C and at Rn < 0.1, while the turbid suspension became transparent at Rn > 0.1. From this turbidity change, an abrupt decrease in ds at the initial stage of the neutralization (Rn < 0.05; see Figure 6) may be attributed to the disaggregation of microgel particles. It appears that in the salt-free system the microgel surfaces are considerably hydrated by water molecules even at 35 °C, while the cross-linked polymers in the particle interior are in a collapse state due to hydrophobic interaction. When NaCl is added to the system, the dehydration due to Na+ and Cl- ions seems to favor the aggregation of the particles. This would enhance an “interparticle” interaction, in other words interactions of the surface functional groups of a particle with those of other particles. If this is the case, the ionization of a few surface COOH groups with NaOH should cause an electrostatic repulsion among the microgel particles to weaken the interparticle interaction. Consequently, we have observed at the same time the initial fall in pKa as well as in ds relating to both the intra- and the

Suzuki et al.

interparticle interactions. Indeed the initial fall in pKa was more clear in 0.1 M NaCl solution than in pure water (see Figure 4). Hydrogen bonding as well as hydrophobic interaction would also be conceivable in both the intraand the interparticle interaction. Conclusions Our titration experiments with NaOH have demonstrated that the ionization characteristics of the COOH groups in both copolymer and gel consisting of NIPA and AAc are very similar. It was suggested that hydrophobic interaction as well as hydrogen bonding plays an important role in the ionization process of the COOH groups, especially at the initial stage of the ionization (Rn < 0.15). The size measurements for the microgel particle were performed under the same conditions as used in the titration. It has become apparent that the changes in the swelling degree caused by Rn and temperature as well as by the absence or the presence of 0.1 M NaCl can be understood at the molecular level by considering the effects of these factors on the ionization of the COOH groups in the gel. In particular, the fact that the gel little swells over 60% ionization of COOH was satisfactorily accounted for in terms of the counterion binding effect generally observed in poly(AAc) solutions. From the results obtained here and in ref 7, we are forced to conclude that the polyelectrolyte gels consisting of NIPA and AAc would swell through an increase in the net charge density due to the COO- ions rather than a rise in osmotic pressure arising from mobile counterions. Acknowledgment. This research was supported by grants to E.K. from the Ministry of Education of Japan (Nos. 09875232 and 08558092). LA981187Z